NO20121306A1 - Apparatus for mixing one fluid into another - Google Patents

Abstract

Apparatus for admixing a fluid into a second, comprising an inlet 10 and an outlet for a first fluid, an outer end 12 of the outlet being designed to be inserted into a tube 11 with a second fluid. The outer end 12 is further provided with one or more openings 13 through which the first fluid can flow. A piston 14 is disposed within the outlet and arranged to form a tight connection to the inner circumference of the outlet and to be movable between an inner position where it closes for all the openings 13, and an outer position where the first fluid can flow out through all the openings at the outer end 12 of the outlet.

Description

Device for mixing one fluid into another

The present invention relates to a device for mixing one fluid into another, in accordance with the introductory part of patent claim 1.

Background

Good water quality is one of the most important criteria for well-being, optimal growth and quality of fish in land-based aquaculture. The water must have the correct temperature, oxygen content, pH and salinity, and this is carefully monitored. The oxygen saturation in the water in the drain from the fish tanks is measured continuously, and the supply of oxygen is adjusted so that the oxygen content is optimal.

According to known technology from the applicant Artec Aqua AS, a partial flow of the water supplied to the plant is enriched with oxygen gas. Water supplied to the plant is referred to below as raw water. The amount of oxygen released to the raw water is controlled by regulating the mixing ratio between incoming raw water and oxygen-enriched raw water, and in known techniques the ratio is regulated by adjusting a diaphragm valve, preferably a pneumatic diaphragm valve.

The problem with this known system is the risk of degassing of oxygen gas after the membrane valve due to reduced pressure in the water between the valve and the mixing point. Degassing results in free gas in the pipes, and this can block the entire water flow to one or more breeding tanks. If the liquid with free gas is fed into the breeding vessel, the gas can lead to flocculation, as well as change the flow pattern of the water in the breeding vessel. Furthermore, free gas cannot be taken up over the gills of the fish, and is therefore considered lost and leads to a poorer economy. The well-known way of mixing oxygenated water in raw water poses a great risk of degassing of already dissolved oxygen, in addition to the fact that in some cases it can redistribute nitrogen gas in the water with the associated risk of "diving sickness". Furthermore, this known solution is vulnerable in that the equipment can be destroyed at low outside temperatures as it is dependent on compressed air dried with an adsorption dryer. The equipment is also expensive to purchase.

Purpose

It is an aim of the present invention to provide a new system for mixing one fluid into another, as the system must provide optimal mixing in a short time. Furthermore, it is an aim that it should be easy and quick to regulate the amount of fluid that is mixed in, for example gas-enriched liquid, and the system should be operationally reliable regardless of weather conditions. Finally, it is an aim that the system should not be expensive to purchase or operate. In a preferred embodiment, a gas-enriched liquid is mixed into another liquid, and the aim is then to avoid problems with degassing before mixing.

The invention

The purpose is achieved with a device in accordance with the characterizing part of patent claim 1. Further advantageous features are provided in the independent claims.

The invention can be used for mixing any fluids, such as gas in gas, gas in liquid, liquid in liquid or liquid in gas. In what follows, the invention is described for mixing water with added oxygen, hereafter referred to as oxygenated water, in raw water, without this being interpreted as limiting the scope of the invention as defined in the claims.

A device in accordance with the present invention comprises an inlet and an outlet for oxygenated water, the outlet being placed inside a pipe through which raw water flows, hereinafter referred to as the main pipe. The outlet is provided with one or more openings through which oxygenated water can flow. Furthermore, a piston is arranged inside the outlet and arranged so that it forms a tight connection against the inner circumference of the outlet, and so that it can be moved between an inner position where it closes all the openings, and an outer position where the oxygenated water can flow out through all the openings. The device is made of any suitable material which is suitable for carrying the liquid or gas which is to flow through it.

The device is attached to the main pipe in any suitable way, which will be obvious to a person skilled in the field, and does not form part of the invention. The transition between the device and the main pipe must be both liquid and gas tight. It is an advantage if the fixing is carried out so that the device can be detached from the main pipe, for example for maintenance.

The device is preferably placed so that the outlet goes perpendicularly into the main pipe, but others

angles may also occur. The outlet should extend some distance into the main pipe, preferably past the center of the main pipe, but not so far as to touch the pipe on the opposite side. The outlet is provided with one or more openings in the periphery, as the openings can be distributed along the circumference and/or along the length of the outlet. The openings form the outlet for the first fluid, and must be at the end of the outlet of the device, so that all the openings are inside the main pipe when the device is mounted.

In a preferred embodiment, the outlet is designed as a pipe connection that extends from the device into the main pipe and radially into the flow of raw water. In this context, "pipe spigot" means a short pipe, as the pipe can otherwise have any shape and design. The pipe spigot can be made of any suitable material which is suitable for carrying both the liquid or gas to be supplied, but also the gas and/or liquid which flows in the main pipe. Furthermore, at least the part of the pipe connector which is fed into the main pipe should have an unchanged internal shape and cross-section, and preferably a smaller outer diameter than the main pipe.

The device further comprises a piston which is guided by a piston rod, in which the piston is arranged inside the outlet and arranged so that a tight connection is formed against the inner circumference of the outlet. The piston is preferably made of POM (polyoxymethylene) or similar material, with a diameter equal to the inner diameter of the outlet. The piston rod extends from the piston and through the device and is connected to an actuator which moves the piston rod and thereby the piston preferably continuously between an inner and outer position.

When the piston is in an internal position, the piston is located inside the outlet between the device and the openings at the end of the outlet. The oxygenated water cannot get past the piston, and therefore no oxygenated water will flow through the device. As the piston is moved towards the outer end of the outlet, the oxygenated water will flow into the outlet and out through the openings located between the piston and the end of the outlet. By regulating the position of the piston, the piston can close parts of the openings so that the area where the oxygenated water can flow out into the raw water is regulated. In designs where the openings are distributed along the longitudinal direction of the outlet, the piston will both regulate the number of openings and the size of the openings through which the oxygenated water can flow out. When the piston is placed in an outer position, it is located at the outer end of the outlet, and oxygenated water flows through all the openings. The flow characteristic out of the outlet depends on the size and shape of the holes, and can be changed/controlled by changing the size and geometry of the openings. For example, symmetrical slots will give a different flow characteristic to triangular or circular openings. In an alternative design, the outlet is replaceable, so that you can replace the outlet with another one with different openings depending on what you want.

In an advantageous embodiment of the present invention, the device is designed so that the piston rod extends in a straight line from the piston in the outlet and through the device. The piston rod is connected to an actuator that pushes the piston rod so that the piston moves between the outer and inner position, and so that the amount of oxygenated water that is mixed into the raw water is regulated.

In a particularly preferred embodiment of the device, the inlet for oxygenated water is angled to the outlet, preferably 90 degrees or more, and in such an embodiment the piston rod can extend in a straight line from the piston and out of the device. The connection between the piston rod and the actuator that pushes on the piston rod can therefore be on the outside of the device itself.

In such a particularly preferred embodiment of the present invention, the actuator can be fixed on top of the device, and connected to the piston rod with a bracket. In this way, a compact unit is achieved that does not need a lot of space. The piston rod will protrude from the device and be moved linearly back and forth by the actuator. In order to avoid that the rod is bent to the side, an advantageous embodiment of the invention is provided with a guide, the bracket connecting the piston rod and the actuator being guided along this.

Example

The invention will be described in the following with reference to the attached figures, where

figure 1 shows a preferred embodiment of the device in accordance with the present invention seen from the side, attached to a pipe carrying raw water,

figure 2 shows the device in figure 1 partially cut through,

figure 3 shows a piston and a piston rod, and

figures 4a-4c show various designs of the outlet on the device.

The device shown in Figures 1 and 2 comprises an inlet 10 and an outlet, the outlet being led into a pipe, hereinafter referred to as main pipe 11, which leads raw water to a land-based breeding facility, a group of breeding vessels or a single breeding tank. The outlet is designed as a pipe connection with an outer end 12 inside the pipe 11 which carries raw water, and an inner end which is connected to the device. The part 12 of the pipe connection which is inside the main pipe 11 is provided with a number of openings 13. Oxygen-enriched water is fed into the inlet 10 of the device, and out through the openings 13 in the outlet. The openings 13 can have different designs, as shown in figures 4a - 4c. In the embodiment shown in figures 1 and 2, the openings are designed as in figure 4a, and the slits 13 are placed so that the oxygen-enriched water will flow radially into the flow of raw water in the pipe, so that optimal mixing between oxygen-enriched water and raw water is achieved.

Inside the pipe socket 12 is arranged a piston 14 which is connected to a piston rod 15, as shown in figures 2 and 3. The piston 14 is arranged or arranged so that it forms a seal against the inside of the outer end 12 of the pipe socket, in the In the embodiment shown, the piston 14 is made of POM and has a diameter that corresponds to the inner diameter of the pipe socket. In the preferred embodiment shown in Figure 3, the piston 14 is connected to the piston rod 15 in that the piston has a through hole which accommodates the piston rod. The through hole may be threaded, matching threads 22 on the outer end of the piston rod. In the embodiment shown in Figure 3, the piston rod 15 is attached to the piston 14 by the piston rod having a constriction 23 at the outer end, so that the piston 14 rests against the step in the constriction 23, and further that a nut 24 is attached on the other side of the piston 14 .. At the opposite end, the piston rod 15 is connected to an actuator 16, the actuator 16 moving the piston rod 15 linearly, thereby moving the piston between an inner and outer position

In the embodiment shown, the outlet is perpendicular to the inlet, and the piston rod 15 extends linearly from the piston 14 out through an opening 17 in the device, at the angle between inlet and outlet. The opening 17 is designed so that the piston rod 15 can be moved linearly through it, but that liquid or gas cannot seep out through it. This can be solved in many ways, which will be obvious to a professional in the field. In this embodiment, the actuator 16 is placed on the outside of the device, and preferably arranged on top of the device so that the piston in the actuator 16 moves parallel to the piston rod 15, and is connected to this by a bracket 18.

In order to avoid the piston rod being bent to the side, as well as to reduce wear on gaskets etc, the device is provided with a guide 19 which extends from the device and at a distance corresponding to the distance between the inner and outer position of the piston 14.1 the embodiment shown, the guide is designed with sides and bottom, as the bracket 18 can rest against the sides and bottom of the guide 19.1 a particularly preferred embodiment, the piston rod 15 is extended, so that the end of the rod is guided through the distal end 20 of the guide both when the piston 14 is in the inner and outer position.

The actuator 16 can be any type of actuator, for example hydraulic, pneumatic or electric, which will be obvious to a person skilled in the art.

When oxygen is to be supplied to the water, the actuator 16 is activated so that the piston 14 is moved towards the outer end 12 of the pipe connector, and oxygen-enriched water flows through the device and out through the openings 13 in the pipe connector. How far the piston 14 should be moved towards the end of the pipe connection depends on how much oxygen is to be supplied to the water, as the piston opens more and/or larger openings 13 the further towards the end it is moved. When the amount of oxygen is to be reduced, or oxygen is no longer to be added to the water, the actuator 16 is activated again, which then moves the piston 14 towards the device so that the openings 13 are completely or partially closed.

In the embodiment shown, the device is provided with a threaded sleeve 21 to optionally be able to fit in a drain, a manometer/pressure transmitter, frost plug or the like. In this way, the pressure can be monitored so that degassing is avoided. The pressure in the device is monitored and compared with the oxygen saturation in the water after mixing in the oxygen-enriched water, so that optimal conditions can be achieved.

The invention is described above with reference to a preferred embodiment shown in the attached figures, and for use in land-based breeding facilities. This has only been done to illustrate the invention and should not under any circumstances be interpreted as limiting the invention as defined in the attached claims.

Claims (10)

1. Device for mixing one fluid into another, comprising an inlet (10) and an outlet for a first fluid, an outer end (12) of the outlet being designed to be led into a pipe (11) with a second fluid, and in that the outer end (12) is provided with one or more openings (13) through which the first fluid can flow, characterized in that a piston (14) is arranged inside the outlet, and arranged so that it forms a tight connection against the inner circumference of the outlet, the piston (14) is arranged movably between an inner position where it closes all the openings (13), and an outer position where the first fluid can flow out through all the openings in the outer end (12) of the outlet. 2. Device in accordance with claim 1, characterized in that the device is designed so that the outer end (12) of the outlet can be arranged radially in the pipe (11) with the second fluid. 3. Device in accordance with claim 1, characterized in that the openings (13) are distributed along the circumference and/or longitudinal extent of the outlet. 4. Device in accordance with claim 1, characterized in that the piston (14) is connected to an actuator (16) via a piston rod (15), so that the actuator (16) can move the piston (14) in relation to the outlet (12). 5. Device in accordance with claim 4, characterized in that the actuator (16) is arranged on the outside of the device. 6. Device in accordance with claim 5, characterized in that the actuator (16) is connected to the piston rod (15) via a bracket (18). 7. Device in accordance with claim 1, characterized in that the inlet and outlet are arranged at an angle to each other. 8. Device in accordance with claim 7, characterized in that a piston rod (15) which is connected to the piston (14) extends linearly from the piston (14) and out of the device at the angle between inlet and outlet. 9. Device in accordance with claim 1, characterized in that the openings (13) in the outlet are slits and that these are distributed along the circumference of the outlet. 10. Device in accordance with claim 9, characterized in that there are two slot-shaped openings (13) in the outlet, and that these are arranged opposite each other so that the fluid will flow radially out into the pipe (11).